Distribution of XML documents/messages to XML appliances/routers

ABSTRACT

XML appliances/routers may be organized to implement one or more XML distribution rings to enable XML documents/messages to be distributed efficiently. The rings may be logical or physical. The XML distribution rings enable the XML documents/messages to be exchanged without requiring the XML appliances/routers to run a routing protocol to determine how XML documents/messages should be distributed through the network. Documents may be transmitted in one way on the ring or may be transmitted in both directions around the ring to enable the ring to tolerate failure of an XML appliance/router. Each XML appliance/router will receive all XML documents/messages and will make routing decisions for those clients that have provided the XML appliance/router with XML subscriptions. The subscriptions may be formed according to the XPath standard or in another manner.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 14/019,608, entitled DISTRIBUTION OF XML DOCUMENTS/MESSAGES TO XML APPLIANCES/ROUTERS, which was filed on Sep. 6, 2013, which was a continuation of Ser. No. 13/679,276, entitled DISTRIBUTION OF XML DOCUMENTS/MESSAGES TO XML APPLIANCES/ROUTERS, which was filed on Nov. 16, 2012, and which issued on Sep. 10, 2013 as U.S. Pat. No. 8,533,267; which was a continuation of U.S. application Ser. No. 11/512,854, entitled DISTRIBUTION OF XML DOCUMENTS/MESSAGES TO XML APPLIANCES/ROUTERS, which was filed on Aug. 30, 2006, and which issued on Nov. 27, 2012 as U.S. Pat. No. 8,321,507, the disclosures of which are incorporated herein by reference in their entirety.

BACKGROUND

1. Field

This application relates to communication networks and, more particularly, to the distribution of XML documents/messages by XML appliances/routers from publishers to subscribers.

2. Description of the Related Art

Data communication networks may include various network elements, such as routers and switches, configured to facilitate the flow of data through the network. Networks may also include other network elements, such as computers and printers, configured to transmit and receive data over the network.

Network elements may have different levels of intelligence, depending on the particular manner in which the network element is intended to operate on the network. For example, a network element may be relatively intelligent and configured to execute software to enable particular applications to be run on the network element, so that the network element can provide services on the network. Alternatively, the network element may be provided with less intelligence and configured to perform a particular service on the network. An example of a less intelligent network element may be a printer connected to the network and configured to provide print services on the network. Optionally, different network elements may work together to collectively provide services on the network. As networks have developed, it has become possible to provide a greater variety of services on the networks.

XML (eXtensible Markup Language) documents/messages may be used to describe network services and to describe other types of information. XML provides a flexible manner to describe services and other information, yet is able to maintain a hierarchical structure. Since XML is well known, a detailed description of XML will not be provided.

Network elements may specify the type of XML documents/messages that are of interest by describing the structure and content of the XML documents/messages. One common way of describing XML documents/messages is to use a common access language referred to generally as XPath. XPath is a standard that has been confirmed by the World Wide Web Consortium (W3C) as a common language to access XML documents/messages. XPath is described in greater detail in XML Path Language XPath Version 1.0, the content of which is hereby incorporated by reference.

XPath may be used to enable a network element to specify which documents/messages a particular user or network element is interested in. This is referred to herein as a subscription. The XPath request will be sent to an XML appliance on the network, which will compare the XPath request against documents/messages that are received at the XML appliance. When the XML appliance receives a document/message that matches the XPath request, it will pass the document/message to the network element that made the request. More generally, when a document/message is published, the XML appliance may look at the structure and content of the documents/messages, compare the published document with known subscription requests, and forward the XML documents/messages to any network element that has expressed an interest in receiving documents of that nature. Thus, an XML document/message may be forwarded to interested applications/users without requiring the publishing network element to address the XML document/message to those applications/users. This is advantageous in that it enables XML documents/messages to be forwarded without requiring the publishing network element to learn the identity/address of the interested applications/users.

Since the structure/content of the XML document/message is used to direct the data through the network to subscribers that are interested in receiving that content, XML is in effect used to route data on the network. This type of muting will be referred to herein as XML routing. XML appliances on the network may be used to perform XML routing so that XML documents/messages may be routed to subscribers based on their content. XML appliances that make routing decisions based on XML content will be referred to herein as XML appliances/routers. Subscribers may advertise subscriptions to particular XML content (using an XPath expression) and the subscriptions may be forwarded to the XML appliances/routers. When an XML appliance/muter receives an XML document/message matching an XML subscription, it will forward the XML document/message toward the subscriber.

FIG. 1 shows an example of a communication network 10 in which an XML appliance 12 is configured to make routing decisions with respect to XML information published by XML publishers 14 and subscribed to by XML subscribers 16. In the embodiment shown in FIG. 1, the XML publishers 14 include one or more servers 18 and the XML subscribers include one or more clients 20. The XML publishers and subscribers, of course, may be network devices other than servers and clients.

Clients 20 may be interested in XML content of a particular type. This interest may be formatted as an XPath subscription request that is then passed to the XML appliance. As XML documents/messages are received by the XML appliance, the XML appliance will check the XML documents/messages against the XPath subscription requests and make routing decisions to forward the XML documents/messages to the interested XML subscribers. Many different matching processes may be used to compare the XML documents/messages against the XPath rules associated with the XPath subscription requests.

XML rules associated with XML subscription requests may be contained in an XML routing table 22 or other memory structure that may be used by the XML appliance to correlate an XPath match with a particular muting decision. For example, the XML appliance may include a table in which entries in the table correlate XPath expression with output port, XPath expression and output interface, XPath expression with tunnel interface, or some other correlation between XPath expression and forwarding action. The muting table will then be used by the XML appliance/router to make XML muting decisions with respect to received XML documents/messages.

FIG. 2 shows an example of a number of XML appliances 12 interconnected to form an XML network. The physical network 13 over which the XML appliances communicate is independent of the network of XML appliances and will be assumed to be capable of interconnecting the XML appliances. Thus, the XML appliances 12 may be physically connected to each other via direct wires, wireless links, or via intermediate network elements such as routers and switches. Data may be tunneled between the XML appliances or otherwise carried by the underlying physical network in any convenient manner, and the network of XML appliances thus may be considered to be independent of the underlying physical network. For example, the XML appliances may be distributed within a larger network such as a LAN, WAN, or the Internet, and interconnected via switches, routers, or other types of network elements. The XML appliances, in this type of network, may exchange information that is then carried, as appropriate, by the underlying physical network interconnecting the XML appliances.

In the example shown in FIG. 2, the XML publishers and XML subscribers are the same as shown above in connection with FIG. 1. However, the intermediate XML network includes a plurality of XML appliances that are interconnected in a mesh or other network arrangement. Specifically, as shown in FIG. 2, the XML appliances have IP addresses 1.1.1.1 through 1.1.1.10. The subscribers are associated with network elements that are connected to XML appliances having IP addresses 1.1.1.7 through 1.1.1.10. Each of the subscribers may request access to XML content by submitting onto the XML network a set of XPath rules that will be transmitted between the XML appliances/routers as XML subscription requests. The XML subscription requests will be distributed throughout the XML network to the XML appliances to enable the XML appliances to make XML routing decisions.

In the embodiment shown in FIG. 2, two examples of XML routing tables have been shown associated with XML appliance 1.1.1.2. Specifically, the first XML routing table 22A shows that content matching XPath rules 1 and 2 should be forwarded to XML appliance 1.1.1.4 while XML content matching XPath rules 3 and 4 should be forwarded using XML appliance 1.1.1.3. This type of correlation may be useful for ingress routing, and optionally other types of XML routing. The example of FIG. 2 also shows a second possible way in which the rules may appear in the XML routing table, in which the XML muting tables designate the end point of a tunnel for the XML content. Specifically, as shown in FIG. 2, the XML routing table 22B may contain a correlation between rule 1 and the destination IP address 1.1.1.10. This enables the content to be tunneled through the network from an XML appliance that makes a decision to the destination of that traffic.

To enable XML appliances/routers to make decisions as to how XML content should be forwarded, the XML appliances/routers have conventionally distributed XML subscription information and built forwarding tables containing XPath expressions. Depending on the configuration of the XML network and the manner in which it the network was set up, XML routing decisions may be made at the ingress to the XML network (by the XML appliance that first receives the XML content), at the egress from the XML network (where the XML content is destined to leave the XML network), by the intermediate XML appliances/routers, or at some other way. XML routes may also be aggregated, hashed, or otherwise manipulated as well to enable efficient decision-making by the XML appliances/routers.

When a subscriber submitted a new XML subscription or modified a previous XML subscription, the XML subscription may be advertised to the XML, appliances/routers using a standard muting protocol such as Open Shortest Path First (OSPF) or Border Gateway Protocol (BOP). However, flooding the network with XML subscriptions may consume significant network overhead, since XML subscriptions may change much more frequently than traditional routing information changes and the amount of information that is required to be transmitted may be much larger than traditional routing information, which may cause the XML routing tables to become rather large.

SUMMARY OF THE DISCLOSURE

As described in greater detail below, XML appliances/routers may be organized into one or more physical or logical ring structures to enable the XML appliances/routers to exchange XML documents/messages in a well defined and low cost manner. The ring structure enables each XML appliance/router to receive XML documents/messages so that it is able to make routing decisions to determine whether any subscribers have expressed an interest in that XML document/message. The XML documents/messages may be passed in one direction around the ring or may be passed in both directions around the ring. When a break in the ring occurs, the XML documents/messages may be passed in the other direction around the ring to enable the XML documents/messages to reach all participants on the ring regardless of the break. The rings may be formed to be logical such as by configuring tunnels between the XML appliances/routers, or may be physical such as by configuring connections between the XML appliances/routers. Other ways of forming the rings may be used as well as discussed in greater detail below.

BRIEF DESCRIPTION OF THE DRAWINGS

Aspects of the present invention are pointed out with particularity in the claims. The (blowing drawings disclose one or more embodiments for purposes of illustration only and are not intended to limit the scope of the invention. In the following drawings, like references indicate similar elements. For purposes of clarity, not every element may be labeled in every figure. In the figures:

FIG. 1 illustrates an example of a communication network having an XML appliance configured to interconnect XML publishers and XML subscribers;

FIG. 2 illustrates a communication network including multiple XML appliances configured to interconnect XML publishers and XML subscribers; and

FIGS. 3-5 illustrate examples of communication networks including multiple XML appliances organized in a ring configured according to an embodiment of the invention; and

FIG. 6 is a functional block diagram of a network management station configured to interface with XML appliances/routers to implement XML distribution rings according to an embodiment of the invention.

DETAILED DESCRIPTION

The following detailed description sets forth numerous specific details to provide a thorough understanding of the invention. However, those skilled in the art will appreciate that the invention may be practiced without these specific details. In other instances, well-known methods, procedures, components, protocols, algorithms, and circuits have not been described in detail so as not to obscure the invention.

By arranging XML appliances/routers to implement one or more XML distribution rings, the XML appliances/routers can distribute XML documents/messages efficiently. Each XML appliance/router will therefore receive all XML documents/messages and will make routing decisions for those clients that have provided the XML appliance/router with XML subscriptions. The subscriptions may be formed according to the XPath standard or in another manner and the invention is not limited to the particular way in which clients subscribe to receive XML documents/messages. The XML distribution rings enable the XML documents/messages to be exchanged without requiring the XML appliances/routers to run a routing protocol to determine bow XML documents/messages should be distributed through the network. For example, because the XML appliances/routers are arranged in one or more ring structures, the XML appliances/routers do not need to run a routing protocol to form a logical spanning tree structure.

FIG. 3 illustrates an example of a logical XML distribution ring 30 in an XML network such as the XML network shown in FIG. 2. As shown in FIG. 3, the XML distribution ring enables XML appliances/routers to forward XML documents/messages to each other on the network and apply local subscription rules to the XML documents to route the XML documents to interested subscribers. In the embodiment shown in FIG. 3, a subscriber associated with XML appliance/router 1.1.1.10 is interested in receiving XML documents/messages that match XPath rule 1. Similarly, a subscriber associated with XML appliance/router 1.1.1.9 is interested in receiving XML documents/messages that match XPath rule 2. XML appliances/routers 1.1.1.10 and 1.1.1.9 are not on a logical distribution ring, however, so they will forward the XPath rules to an adjacent XML appliance/router until the rules are received by an XML appliance/router that is on an XML document/message distribution ring. In the illustrated example, XML appliance/router 1.1.1.5 is on an XML document/message distribution ring 30, and accordingly the rules (rule 1 and rule 2) will be programmed into that XML appliance/router's forwarding table 31.

When XML content such as an XML document/message enters the XML document/message distribution ring, it will be passed in one direction or in both directions around the ring so that XML appliances/routers on the ring may receive the XML content. The XML distribution ring enables XML appliances/routers to have a defined way in which to exchange XML documents/messages so that XML subscriptions need not be advertised or broadcast on the network. Additionally, having the XML distribution ring defined in this manner enables the XML appliances routers to forward XML content without running a routing protocol that could then be used to calculate a distribution tree. The use of a ring structure also may provide redundancy where the ring is bi-directional, so that a failure of one of the XML appliances/routers will not prevent other XML appliances/routers from receiving the XML documents/messages.

Table 1 below shows several possible distribution orders that may be used to transmit XML documents/messages around the example ring:

TABLE I Example No. Distribution order 1 1.1.15 → 1.1.1.4 → 1.1.1.1 → 1.1.1.2 → 1.1.1.3 → 1.1.1.6 → 1.1.1.5 2 1.1.15 → 1.1.1.6 → 1.1.1.3 → 1.1.1.2 → 1.1.1.1 → 1.1.1.4 → 1.1.1.5 3 1.1.15 → 1.1.1.4 → 1.1.1.1 → 1.1.1.2 → 1.1.1.3 → 1.1.1.6 → 1.1.1.5 and 1.1.15 → 1.1.1.6 → 1.1.1.3 → 1.1.1.2 → 1.1.1.1 → 1.1.1.4 → 1.1.1.5 4 1.1.15 → 1.1.1.4 → 1.1.1.1 → 1.1.1.2 and 1.1.15 → 1.1.1.6 → 1.1.1.3 → 1.1.1.2

As shown in Table 1, there are several ways in which XML documents/menages may be transmitted around the XML distribution ring. In Example No. 1, XML documents/messages are distributed in a counterclockwise direction around the logical ring of XML appliances/routers. In Example No. 2, the XML documents/messages are distributed clockwise. In both examples 1 and 2, when the XML documents/messages reaches the XML appliance/router that originated the distribution, they will stop and not be further forwarded on the ring. This prevents XML documents/messages from continuing to circle the logical XML distribution ring. Additionally, this enables the original XML appliance/router to confirm that all XML appliances/routers on the ring have received the XML documents/messages.

In Example Nos. 3 and 4, the XML documents/messages are distributed in both directions starting at the XML appliance/router where the XML documents/messages entered the ring. The XML documents/messages may traverse all the way around the ring to the originating XML appliance/router as shown in Example No. 3, or transmission of the XML documents/messages may be terminated once it catches up with the same information being transmitted the other way on the logical XML distribution ring as shown in Example No. 4. In either instance, the XML appliance/router that terminates distribution of the XML documents/messages is able to ensure that all other XML appliances/routers have seen the XML document/message, the distribution of which is being terminated.

Termination of distribution of the XML documents/messages on the ring in Example No. 4 may be enabled in many ways, for example by causing the XML appliances/routers to check whether a received XML document/message is a duplicate of a XML document/message that was previously forwarded by the XML appliance router. By not forwarding duplicate XML documents/messages, the amount of XML documents/messages being forwarded around the ring may be reduced. Other ways of terminating distribution around the ring may be used as well, such as by counting hops that the XML document/message has taken on the ring, looking for XML documents/messages from a particular XML appliance/muter, or in other ways.

FIG. 4 shows an example of en XML distribution ring in which a failure 34 has occurred between XML appliances/routers A and G. Although the XML appliances/routers may be interconnected by an underlying physical network having failure protection mechanisms, and thus a failure on the logical ring may be expected to occur relatively infrequently, a failure may still occur that would require XML documents/messages to propagate in both directions around the ring. For example, one of the XML appliances/routers may fail which would break the ring and require the XML documents/messages to propagate in both directions around the ring.

In the example shown in FIG. 4, assume that XML document/message is passed onto the ring via XML appliance/router B. If the ring is configured to transmit the XML documents/messages clockwise, the XML document/messages will be passed to XML appliances/routers C, D, E, F, and G. However, the failure 34 will prevent the XML documents/messages from reaching XML appliance/router A.

To enable the distribution ring to tolerate failure, the original sending XML appliance/router B may be configured to maintain state information for each XML document/message transmission and wait to receive a matching transmission on the ring. When the original sending XML appliance/router receives a copy of the XML document/message, it knows that the transmission has traversed the entire ring and that all of the XML appliances/routers on the ring have received the transmission. If the original sending XML appliance/router does not receive a confirming transmission, the original XML sending router may transmit the same transmission in the other direction on the ring to enable the transmission to traverse the ring in the other direction until it reaches a break in the ring. This process will enable a logical XML ring to tolerate a break in the XML ring. In the illustrated example, if XML appliance/router B does not receive a duplicate transmission confirming the ring is in-tact within a given time period, XML appliance/router B may retransmit the duplicate XML documents/messages transmission in the other direction on the ring which, in this example, is toward XML appliance/router A.

Alternatively, XML appliances/routers may be configured to determine when there is a break in the XML distribution ring such as by issuing confirmations or other connection keep-alive messages. Where an XML appliance/router determines that there is a failure on the XML distribution ring, the XML appliance/router may be configured to re-transmit the XML documents/messages transmission in the opposite direction on the ring to cause the XML documents/messages transmission to go the other way on the ring to reach the XML appliances/routers on the apposite side of the break.

XML appliances/routers use subscription information to forward XML documents/messages to local subscribing clients. The subscription information may be in the form of an XPATH expression, a textual pattern matching language such as General Regular Expression Parser (MEP) or which may take another form. The subscribers may be locally attached or may be attached to the XML distribution ring via one or more intermediate XML appliances/routers.

A given network may grow to be relatively large such that it may not be practical to have a single logical XML distribution ring including all of the XML appliances/routers on the network. Accordingly, as shown in FIG. 5, multiple XML distribution rings may be implemented to enable distribution of XML documents/messages to the MAL appliances/routers on a network. In the example illustrated in FIG. 5, a network including XML appliances/routers A-L has two rings—a first ring which is similar to the ring discussed in connection with FIG. 4 (Ring 1=A, B, C, D, E, F, G, A) and a second ring (Ring 2) including routers C, H, I, J, K, L, D, C. Clients and servers may be located on either ring.

When an XML document/message is transmitted on one of the rings and reaches a router that is on more than one ring, that XML appliance/router will transmit the XML document/message onto all of the rings of which it is a member. Thus, for example, when XML appliance/router C receives an XML document/message from XML appliance/router B on ring 1, it will transmit the XML document/message both to XML appliance/router D on Ring 1 and to XML appliance/router H on Ring 2. In connection with this, the manner in which the two rings are configured to transmit XML documents/messages may make a difference as to how the XML appliances/routers behave. For example, if Ring 1 is configured to distribute XML documents/messages clockwise and Ring 2 is configured to distribute XML documents/messages counterclockwise, XML appliance/router C may simply pass the XML document/message to XML appliance/router D since XML appliance/router C is not a transmission junction between the two rings. At XML appliance/router D, in this example, the distribution of XML documents/messages would diverge, however, and XML appliance/router D may be configured to transmit copies of the XML documents/messages on both XML distribution rings. Thus, in this example, XML appliance/router D would be configured to transmit a copy of the XML document/message to XML appliances/routers E and L.

As shown in FIG. 5, each ring may be operated independent of the other rings on the network. When XML documents/messages are transmitted from one ring to another, the XML appliance/router that first transmits the XML document/message on the ring will be considered the originating muter for that information on the ring to ensure that the information reaches all XML appliances/routers on the ring.

Although two rings have been illustrated in this example network, the invention is not limited in this manner as any number of rings may be used to transmit XML documents/messages on the network. The number of nodes on a ring may vary depending on the rate at which the XML documents/messages are able to be retransmitted by the XML appliances/routers and the amount of time the network can tolerate between initial transmission of XML documents/messages to the ultimate reception of the XML documents/messages by all of the XML appliances/routers on the network. For example, the rings may have between 5 and 20 XML appliances/routers, although the invention is not limited to this particular range.

The XML appliances may be commonly available XML appliances/routers such as the DataPower XS40 XML Secure Gateway. The invention is not limited in this manner, however, as other XML appliances/routers, both in existence and to be developed, may be used in connection with embodiments of the invention to enable XML documents/messages to be distributed on a network of XML appliances/routers.

The rings of XML appliances/routers on the network may be established using network management software running on a network management station 36 interfacing with the XML appliances/routers for example via Simple Network Management Protocol (SNMP). Configuration of the rings may be established by setting MIB variables indicative of how XML documents/messages should be forwarded by an XML appliance/router or by setting values in the routing tables of the XML appliances/routers to cause the XML documents/messages to be forwarded to implement the XML rings. The invention is not limited to these several described ways of programming the XML appliances/routers to establish the XML content distribution rings as other ways of causing the XML appliances/routers to implement the rings may be used as well.

FIG. 6 illustrates an example of a network management station including network management software configured to implement XML distribution rings on a network of XML appliances/routers. As shown in FIG. 6, the network management station 36 may be implemented as a computer/server on a network that includes a processor 60 including control logic 62. The control logic may be configured to implement management software 66 to enable the management station to interact with and program the XML appliances/routers. The management software may be configured, for example, to establish the XML distribution ring(s) by instructing the XML appliances/routers how to forward XML documents/messages on the network of XML appliances/routers. The management software may interface a database of XML appliance/router network topography so that the management software or a network administrator using the management software may determine how the XML distribution rings should be formed on the network.

The management station 36 may also include many other factional aspects that are commonly associated with computers/servers, such as a network interface 64 and other common functional components. The invention is not limited to the particular hardware platform chosen to implement the network management station as many different types of network elements may be used to implement the network management station.

It should be understood that all functional statements made herein describing the functions to be performed by the methods of the invention may be performed by software programs implemented utilizing subroutines and other programming techniques known to those of ordinary skill in the art. Alternatively, these functions may be implemented in hardware, firmware, or a combination of hardware, software, and firmware. The invention is thus not limited to a particular implementation but rather extends to all manners of implementing the functions described herein in connection with XML appliances/routers on an XML network.

It should be understood that various changes and modifications of the embodiments shown in the drawings and described herein may be made within the spirit and scope of the present invention. Accordingly, it is intended that all matter contained in the above description and shown in the accompanying drawings be interpreted in an illustrative and not in a limiting sense. The invention is limited only as defined in the following claims and the equivalents thereto. 

What is claimed is:
 1. A method of distributing information formatted in a markup language in a network of network nodes interconnected by communication links, the network nodes being configured: to make routing decisions for the information formatted in the markup language by applying markup language subscription information to the information formatted in the markup language; and to forward the information formatted in the markup language toward subscribing clients according to the markup language subscription information; the method comprising: establishing a network topology in the network of network nodes for the distribution of the information formatted in the markup language between the network nodes; coupling subsets of subscribing clients to the network respective originating network nodes; enabling the respective originating network nodes to transmit information formatted in the markup language on the network; and operating the network nodes: to receive markup language subscription information from respective subsets of subscribing clients; to locally apply the markup language subscription information to respective information formatted in the markup language; to select respective information formatted in the markup language to be forwarded to respective subsets of subscribing clients without exchanging markup language subscription information between network nodes; and to forward the selected information formatted in the markup language toward respective subscribing clients according to the markup language subscription information submitted by the subscribing clients.
 2. The method of claim 1, wherein the network topology comprises at least one set of serially connected network nodes.
 3. The method of claim 2, wherein enabling the respective originating network nodes to transmit information formatted in the markup language on the network comprises configuring the network nodes to transmit the information formatted in the markup language in either direction between serially connected network nodes.
 4. The method of claim 2, wherein the at least one set of serially connected network nodes comprises at least one distribution ring.
 5. The method of claim 4, wherein enabling the respective originating network nodes to transmit information formatted in the markup language on the network comprises configuring the network nodes to transmit the information formatted in the markup language in either direction on the at least one distribution ring.
 6. The method of claim 4, wherein enabling the respective originating network nodes to transmit information formatted in the markup language on the network comprises configuring the network nodes to transmit the information formatted in the markup language in both directions on the at least one distribution ring.
 7. The method of claim 4, comprising terminating the transmission of information formatted in the markup language on the distribution ring.
 8. The method of claim 7, wherein terminating the transmission of information formatted in the markup language on the distribution ring comprises terminating the transmission of respective information formatted in the markup language at a respective originating network node which transmitted the respective information formatted in the markup language onto the distribution ring.
 9. The method of claim 1, wherein the network topology is a logical network topology.
 10. The method of claim 9, wherein the network nodes are interconnected by a physical network including intermediate network elements and the network nodes are configured to transmit the information formatted in the markup language between network nodes by tunneling the information formatted in the markup language across the physical network.
 11. The method of claim 4, wherein the at least one distribution ring comprises at least one logical distribution ring.
 12. The method of claim 11, wherein the network nodes are interconnected by a physical network including intermediate network elements and the network nodes are configured to transmit the information formatted in the markup language between network nodes by tunneling the information formatted in the markup language across the physical network.
 13. The method of claim 1, comprising terminating the transmission of respective information formatted in the markup language at a respective network node.
 14. The method of claim 13, comprising terminating the transmission of the respective information formatted in the markup language at the respective network node when the respective network node determines that respective information formatted in the markup language need not be distributed further on the network.
 15. The method of claim 1, wherein the network topology is established administratively.
 16. The method of claim 1, wherein the network topology is established by a network management program.
 17. The method of claim 16, wherein the network topology is established by a network management program using Simple Network Management Protocol (SNMP).
 18. The method of claim 1, wherein the information formatted in the markup language comprises messages formatted in the markup language.
 19. The method of claim 1, wherein the information formatted in the markup language comprises documents formatted in the markup language.
 20. The method of claim 1, wherein the markup language is Extensible Markup Language (XML). 